kubespray/docs/vagrant.md

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Vagrant

Assuming you have Vagrant 2.0+ installed with virtualbox or libvirt/qemu (vmware may work, but is untested) you should be able to launch a 3 node Kubernetes cluster by simply running vagrant up.

This will spin up 3 VMs and install kubernetes on them. Once they are completed you can connect to any of them by running vagrant ssh k8s-[1..3].

To give an estimate of the expected duration of a provisioning run: On a dual core i5-6300u laptop with an SSD, provisioning takes around 13 to 15 minutes, once the container images and other files are cached. Note that libvirt/qemu is recommended over virtualbox as it is quite a bit faster, especially during boot-up time.

For proper performance a minimum of 12GB RAM is recommended. It is possible to run a 3 node cluster on a laptop with 8GB of RAM using the default Vagrantfile, provided you have 8GB zram swap configured and not much more than a browser and a mail client running. If you decide to run on such a machine, then also make sure that any tmpfs devices, that are mounted, are mostly empty and disable any swapfiles mounted on HDD/SSD or you will be in for some serious swap-madness. Things can get a bit sluggish during provisioning, but when that's done, the system will actually be able to perform quite well.

Customize Vagrant

You can override the default settings in the Vagrantfile either by directly modifying the Vagrantfile or through an override file. In the same directory as the Vagrantfile, create a folder called vagrant and create config.rb file in it. An example of how to configure this file is given below.

Use alternative OS for Vagrant

By default, Vagrant uses Ubuntu 18.04 box to provision a local cluster. You may use an alternative supported operating system for your local cluster.

Customize $os variable in Vagrantfile or as override, e.g.,:

echo '$os = "flatcar-stable"' >> vagrant/config.rb

The supported operating systems for vagrant are defined in the SUPPORTED_OS constant in the Vagrantfile.

File and image caching

Kubespray can take quite a while to start on a laptop. To improve provisioning speed, the variable 'download_run_once' is set. This will make kubespray download all files and containers just once and then redistributes them to the other nodes and as a bonus, also cache all downloads locally and re-use them on the next provisioning run. For more information on download settings see download documentation.

Example use of Vagrant

The following is an example of setting up and running kubespray using vagrant. For repeated runs, you could save the script to a file in the root of the kubespray and run it by executing source <name_of_the_file>.

# use virtualenv to install all python requirements
VENVDIR=venv
virtualenv --python=/usr/bin/python3.7 $VENVDIR
source $VENVDIR/bin/activate
pip install -r requirements.txt

# prepare an inventory to test with
INV=inventory/my_lab
rm -rf ${INV}.bak &> /dev/null
mv ${INV} ${INV}.bak &> /dev/null
cp -a inventory/sample ${INV}
rm -f ${INV}/hosts.ini

# customize the vagrant environment
mkdir vagrant
cat << EOF > vagrant/config.rb
\$instance_name_prefix = "kub"
\$vm_cpus = 1
\$num_instances = 3
\$os = "centos-bento"
\$subnet = "10.0.20"
\$network_plugin = "flannel"
\$inventory = "$INV"
\$shared_folders = { 'temp/docker_rpms' => "/var/cache/yum/x86_64/7/docker-ce/packages" }
EOF

# make the rpm cache
mkdir -p temp/docker_rpms

vagrant up

# make a copy of the downloaded docker rpm, to speed up the next provisioning run
scp kub-1:/var/cache/yum/x86_64/7/docker-ce/packages/* temp/docker_rpms/

# copy kubectl access configuration in place
mkdir $HOME/.kube/ &> /dev/null
ln -s $PWD/$INV/artifacts/admin.conf $HOME/.kube/config
# make the kubectl binary available
sudo ln -s $PWD/$INV/artifacts/kubectl /usr/local/bin/kubectl
#or
export PATH=$PATH:$PWD/$INV/artifacts

If a vagrant run failed and you've made some changes to fix the issue causing the fail, here is how you would re-run ansible:

ansible-playbook -vvv -i .vagrant/provisioners/ansible/inventory/vagrant_ansible_inventory cluster.yml

If all went well, you check if it's all working as expected:

kubectl get nodes

The output should look like this:

$ kubectl get nodes
NAME    STATUS   ROLES                  AGE     VERSION
kub-1   Ready    control-plane,master   4m37s   v1.22.5
kub-2   Ready    control-plane,master   4m7s    v1.22.5
kub-3   Ready    <none>                 3m7s    v1.22.5

Another nice test is the following:

kubectl get pods --all-namespaces -o wide

Which should yield something like the following:

$ kubectl get pods --all-namespaces -o wide
NAMESPACE            NAME                                      READY   STATUS    RESTARTS   AGE     IP            NODE    NOMINATED NODE   READINESS GATES
kube-system          coredns-8474476ff8-m2469                  1/1     Running   0          2m45s   10.233.65.2   kub-2   <none>           <none>
kube-system          coredns-8474476ff8-v5wzj                  1/1     Running   0          2m41s   10.233.64.3   kub-1   <none>           <none>
kube-system          dns-autoscaler-5ffdc7f89d-76tnv           1/1     Running   0          2m43s   10.233.64.2   kub-1   <none>           <none>
kube-system          kube-apiserver-kub-1                      1/1     Running   1          4m54s   10.0.20.101   kub-1   <none>           <none>
kube-system          kube-apiserver-kub-2                      1/1     Running   1          4m33s   10.0.20.102   kub-2   <none>           <none>
kube-system          kube-controller-manager-kub-1             1/1     Running   1          5m1s    10.0.20.101   kub-1   <none>           <none>
kube-system          kube-controller-manager-kub-2             1/1     Running   1          4m33s   10.0.20.102   kub-2   <none>           <none>
kube-system          kube-flannel-9xgf5                        1/1     Running   0          3m10s   10.0.20.102   kub-2   <none>           <none>
kube-system          kube-flannel-l8jbl                        1/1     Running   0          3m10s   10.0.20.101   kub-1   <none>           <none>
kube-system          kube-flannel-zss4t                        1/1     Running   0          3m10s   10.0.20.103   kub-3   <none>           <none>
kube-system          kube-multus-ds-amd64-bhpc9                1/1     Running   0          3m2s    10.0.20.103   kub-3   <none>           <none>
kube-system          kube-multus-ds-amd64-n6vl8                1/1     Running   0          3m2s    10.0.20.102   kub-2   <none>           <none>
kube-system          kube-multus-ds-amd64-qttgs                1/1     Running   0          3m2s    10.0.20.101   kub-1   <none>           <none>
kube-system          kube-proxy-2x4jl                          1/1     Running   0          3m33s   10.0.20.101   kub-1   <none>           <none>
kube-system          kube-proxy-d48r7                          1/1     Running   0          3m33s   10.0.20.103   kub-3   <none>           <none>
kube-system          kube-proxy-f45lp                          1/1     Running   0          3m33s   10.0.20.102   kub-2   <none>           <none>
kube-system          kube-scheduler-kub-1                      1/1     Running   1          4m54s   10.0.20.101   kub-1   <none>           <none>
kube-system          kube-scheduler-kub-2                      1/1     Running   1          4m33s   10.0.20.102   kub-2   <none>           <none>
kube-system          nginx-proxy-kub-3                         1/1     Running   0          3m33s   10.0.20.103   kub-3   <none>           <none>
kube-system          nodelocaldns-cg9tz                        1/1     Running   0          2m41s   10.0.20.102   kub-2   <none>           <none>
kube-system          nodelocaldns-htswt                        1/1     Running   0          2m41s   10.0.20.103   kub-3   <none>           <none>
kube-system          nodelocaldns-nsp7s                        1/1     Running   0          2m41s   10.0.20.101   kub-1   <none>           <none>
local-path-storage   local-path-provisioner-66df45bfdd-km4zg   1/1     Running   0          2m54s   10.233.66.2   kub-3   <none>           <none>